CN101158985B - Ultra-dimension fluvial dynamics self-adapting parallel monitoring method - Google Patents
Ultra-dimension fluvial dynamics self-adapting parallel monitoring method Download PDFInfo
- Publication number
- CN101158985B CN101158985B CN2007101243161A CN200710124316A CN101158985B CN 101158985 B CN101158985 B CN 101158985B CN 2007101243161 A CN2007101243161 A CN 2007101243161A CN 200710124316 A CN200710124316 A CN 200710124316A CN 101158985 B CN101158985 B CN 101158985B
- Authority
- CN
- China
- Prior art keywords
- dimension
- partiald
- super
- parallel
- data
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Images
Landscapes
- Management, Administration, Business Operations System, And Electronic Commerce (AREA)
Abstract
The invention discloses a method of super-dimensional river dynamics self-adaptive parallel monitoring, which includes the steps as following: inputting super-dimensional data into a system and classifying according to the different dimension where the data are; creating a super-dimensional unstructured grid river dynamics model based on a characteristic-type high-resolution numerical algorithm; in terms of an efficient parallel algorithm in a super-dimensional fluid splitting scheme, performing intra-dimensional and inter-dimensional calculations; dividing the calculation region into a plurality of sub-regions, wherein each sub-region is mapped on a calculation node on the parallel system structure, the communication between the nodes uses a standard message passing interface, the overlapped parallel optimization technique of calculation and communication in the self-adaptive grid, and the calculation of variables associated with the space is independent; and finally comparing and analyzing the data and change law. The method in the invention puts the super-dimensional river dynamics into the adaptive grid to execute the efficient parallel calculation of splitting scheme, and simultaneously processes the change of dimension; the method realizes the monitoring of river conveniently, timely and high accurately.
Description
Technical field
The present invention is mainly concerned with a kind of dynamics monitoring method of water conservancy, particularly relate to a kind of parallel calculating method, also relate to a kind of simultaneously based on the modeling preprocess method of ultra-dimension fluvial dynamics and novel river monitoring method based on tag type high resolving power numerical algorithm and the non-structured grid river dynamics of super dimension model based on adaptive mesh.
Background technology
Present field, digital basin mainly concentrates on a peacekeeping two dimension for the research of river dynamics, to produce the simulation of river course, the network of waterways etc., the professional etiquette of going forward side by side is drawn, it is ripe and deep that is that all right aspect the fluid simulation of three-dimensional, the efficient parallel of the three-dimensional division of fluid commonly used form calculates, and its fluid continuity equation differential form is
Wherein, ρ is a fluid density, and μ is a speed.
It is Q that the zone is calculated in design
T∈ (0, II) * (0, JJ) * (0, KK) * (0, T), use parallel lines x=x
i=i Δ x (i=1,2 ..., II), y=y
j=j Δ y (i=1.2 ..., JJ), z=z
k=k Δ z (i=1,2 ..., KK) and t=t
n=n Δ t is cut apart the zoning, i Δ x=ii here, and j Δ y=jj, K Δ z=KK, N Δ t=T, I, J, K and N are positive integer, Δ x, Δ y, Δ z and Δ t are divided into space lattice step-length and time step.Space step-length and time step such as suppose.
Providing the pro forma division form of continuity equation, the value of being arranged by the n time is asked the value that the n+1 time arranges, and its computation process was divided into for 3 steps, and the difference scheme discrete with direction is example, and other directions roughly the same.
Here, f represents the density in the continuity equation, and α represents the coefficient of difference equation on the x direction.
Whole flow region is divided into the N sub regions distributes to N CPU calculating, the initial flow-field information of subregion, geological information (mesh coordinate, identification number) are respectively loaded in the internal memory of CPU of all subregion correspondence, in each CPU, start calculation procedure, dispatch the calculating of each CPU by host process.In the scanning process of the whole audience each time, finish the calculating of subregion and finish exchanges data (being the communication between each CPU) on the border by each CPU, collect whole audience data by host process and finish convergence criterion and differentiate, and write dish on demand and wait other operation.
Under the fixed situation of physical model and numerical algorithm, computing velocity depends primarily on cpu performance, CPU number, internal memory, CPU-EMS memory access bandwidth, node interconnecting bandwidth, mesh quality and subregion quality etc.Each particular problem, each particular machine are corresponding to an optimally partitioned number, and a large amount of practice meetings sums up an optimal mesh number/CPU ratio to same class problem.The number of partitions is too much, and the traffic increases between CPU, and the number of partitions increases to a certain degree can reduce computing velocity on the contrary; The number of partitions is very few, does not make full use of more CPU and participates in calculating, and also can influence computing velocity; Subregion is of poor quality, and each cpu load is inhomogeneous, and CPU has the wait phenomenon, also influences speed.
Usually ripe commercial packages as FLUENT, all provides two kinds of partition methods at least: auto-partition and manual subregion.The benefit of auto-partition is easy and simple to handle, and suitable engineering is used, the assurance surely but load balance of each CPU differs.Manually subregion is just the opposite.It should be noted that, for stable-state flow, calculate a series of data messages that all only keep whole field in the moment internal memory at any one,, need not to visit disk so in computation process, only there is the communication between CPU-internal memory, the CPU-CPU (or calculating node-calculating node).
But for non-permanent problem, each time step all produces series of fields information, and the field information that each must be calculated node after each time step calculates and finishes can gather, and carries out the write operation of internal memory to disk, and this moment, the traffic increased suddenly, and computing velocity can slow down undoubtedly.
Aspect flow mechanism research, the Region Segmentation parallel method still widely uses.(Lawrence Livermore National Laboratory has just adopted this method when USA) studying turbulent flow and non-stationarity thereof as U.S. Lao Lunsilifo More laboratory.Because the scale of turbulence is minimum,, thereby make the grid number of whole zoning reach billions of so grid resolution must be less than the scale of turbulence.
Along with the development of river dynamics and the requirement of large watershed large scale scene, three-dimensional processing can't have been satisfied the research requirement of hydraulic engineering.Need to inject the information of super dimension, promptly divide extraction, make up tables of data and database, to make things convenient for parallel processing, for example: geographical space dimension, the i.e. geographic position in river with certain format by super dimension data being carried out dimension; Time dimension, reflection continually varying attribute; The relevant information dimension, comprise that water conservancy information (as water level, rainfall, flow, worker's feelings data etc.) and the society relevant with water conservancy are through information (as population, economy, soil etc.) or the like, and along with research deeply and the special circumstances of different demands, the variation of dimension and to increase be inevitable.
Therefore, prior art has yet to be improved and developed.
Summary of the invention
One of purpose of the present invention is fast inadequately for the speed that overcomes river dynamics monitoring processing commonly used at present, and the calculating validity under calculated amount increases reduces, and to the simulate effect of realistic situation and problem limited in one's ability.
Two of purpose of the present invention is in order to overcome the poorness of low latitude information, to surpass dimension data input system after simple pre-service, and classify according to the difference of data dimension of living in, set up the novel non-structured grid river dynamics of super dimension model based on tag type high resolving power numerical algorithm, and division of utilization dimension and adaptive mesh parallel processing, monitor foundation comparatively accurately to provide.
To achieve these goals, the invention provides a kind of method of ultra-dimension fluvial dynamics self-adapting parallel monitoring, this method comprises the steps:
A, set up the fundamental equation model of various dimensions, will surpass the dimension data input system, classify according to the difference of data dimension of living in; Wherein, super dimension comprises: geographical space dimension, time dimension and relevant information dimension; Described relevant information dimension comprises: water conservancy information and the society relevant with water conservancy are through information;
B, based on the extracting of satellite photo and river hydrology data, the form of multiple information condition with boundary condition joined in the fundamental equation, set up the non-structured grid river dynamics of super dimension model based on tag type high resolving power numerical algorithm; Wherein, boundary condition is: Free Surface border and bottom boundary should satisfy corresponding kinematic and dynamic conditions, and circle, bank normal direction flow velocity is zero; Then given water level in border or flow velocity are opened in the waters;
The efficient parallel computing method of C, the super dimension fluid division of foundation form are carried out interior calculating of dimension and the calculating between dimension;
D, the zoning is divided into a plurality of subregions, each subregion is mapped on the parallel architecture one and calculates on the node, the message passing interface of standard is adopted in communication between node, adopt in adaptive mesh and calculate and the overlapping parallel optimization technology of communicating by letter, variable is independent about the calculating in space;
Adaptive mesh adopts the insertion generation gradually of super triangle among the described step D, comprises that step is as follows:
D1, the super triangle of formation universe;
D2, divergent boundary insert frontier point in order;
D3, search comprise the triangle of this frontier point, and this triangle is decomposed into 3 triangles; Repeat above-mentioned D2~D3 step, up to finishing all borders;
D4, delete the triangle that all comprise one or more super triangular apex;
D5, according to mesh scale control, encrypt the triangulation network, meet the triangular mesh of yardstick up to formation;
D6, grid optimization;
E, set up the ultra-dimension fluvial dynamics numerical model of vertical sigma coordinate based on non-structured grid finite volume method, model adopts quadrilateral and triangle hybrid grid, and the result who calculates gained is carried out data and Changing Pattern comparative analysis.
Described method, wherein, the parallel computation process of described step C comprises:
C1, calculate the internal boundary points on each processor, promptly be defined in the frontier point of the subregion of each processor, do not comprise the natural boundary point of finding the solution the zone about certain direction;
C2, the data of the internal boundary points on this direction are carried out the message transmission;
C3, calculate in point, promptly be defined in the non-frontier point of the subregion on each processor.
The method of a kind of ultra-dimension fluvial dynamics self-adapting parallel monitoring provided by the present invention is applicable to the effective extraction Treatment Analysis based on ultra-dimension fluvial information, can reflect the river Changing Pattern under the super dimension analysis conscientiously; By the super dimension non-structured grid river dynamics model of utilization based on tag type high resolving power numerical algorithm, carry out the mapping and the calculating of ultra-dimension fluvial dynamics, its processing speed is fast; Ultra-dimension fluvial dynamics in adaptive mesh, is divided the parallel computation of form efficiently, and handle the variation of dimension simultaneously, its monitoring that realizes the river is in time convenient, the accuracy height.
Description of drawings
Fig. 1 is the processing flow chart of the inventive method;
Fig. 2 is the hardware system synoptic diagram of the inventive method;
Fig. 3 is the logical organization synoptic diagram of the inventive method.
Embodiment
With reference to accompanying drawing, will be described in detail the method for the invention.
The method of ultra-dimension fluvial dynamics self-adapting parallel monitoring of the present invention, the processing design of its core is, to surpass dimension data and after simple pre-service, import generic processing system, and classify according to the difference of data dimension of living in, set up the novel non-structured grid river dynamics of super dimension model based on tag type high resolving power numerical algorithm, efficient parallel computing method according to super dimension fluid division form, carry out interior calculating of dimension and the calculating between dimension, the zoning is divided into a plurality of subregions, each subregion is mapped on the parallel architecture one and calculates on the node, the MPI of standard is adopted in communication between node, adopt in adaptive mesh and calculate and the overlapping parallel optimization technology of communicating by letter, variable is independently about the calculating in space.
The process of setting up of described river dynamics model comprises, based on extracting of satellite photo and hydrology geodata, the form of multiple information condition with boundary condition is joined in the three-dimensional flow fundamental equation, thereby form this model.
The hardware that the inventive method adopted is a multi-purpose computer or high-performance computer HPC, as shown in Figure 2, it comprises a 3D interactive operation display platform, the high-performance calculation platform, the real-time acquisition process platform of large-scale data, described display platform are for the three-dimensional display system content and can carry out real-time interoperability; Described high-performance calculation platform provides powerful computing ability and processing speed efficiently; The acquisition process platform can accept to detect hydrology geodata etc. fast, and handle etc.The system logic structure that the inventive method adopted, as shown in Figure 3, it comprises parallel data and model bank, concurrent computational system, and 3D operation interactive system.
As shown in Figure 1, be the process flow diagram of a kind of preferred implementation of the inventive method, it may further comprise the steps:
Continuity equation
The equation of momentum
U, υ, ω are respectively the component of velocity along three coordinate axis x, y, z in the formula; τ
IjBe shearing stress; F is the Ke Shi force coefficient, f=2 ω sin Ψ; Ψ is a local latitude; ω is a rotational-angular velocity of the earth.
Convert Cartesian coordinate to the sigma coordinate, promptly (x, y, z) → (x, y σ), can get:
Continuity equation
The equation of momentum
In the formula
H is the depth of water; Z is a water level; ξ is the Free Surface height; ω is the vertical flow velocity under the σZuo Biao; The horizontal proliferation item
E
υBe the vertical diffusion coefficient.
Vertical velocity ω and the vertical velocity ω transformational relation in the z coordinate system in the σZuo Biao system are as follows:
ω in the formula (0)=ω (1)=0.For ease of follow-up modeling, write formula (5)~formula (7) as following unified vector form:
In the formula
Dependent variable replaces depth of water h with Free Surface height ξ in this system of equations form, can avoid hydrostatic to calculate discordant problem.
Wherein, boundary condition is: Free Surface border and bottom boundary should satisfy corresponding kinematic and dynamic conditions, and circle, bank normal direction flow velocity is zero; Then given water level in border or flow velocity are opened in the waters.
The fundamental equation of each dependent variable is formula (5)~formula (8), and wherein Free Surface height ξ calculates by formula (10).The employing explicit scheme is discrete, and the specific implementation process of algorithm is as follows:
1) the numerical value net flux of layering computing unit horizontal direction;
2) the unit horizontal numerical value net flux that calculates along the vertical average first step according to formula (10), can calculate the Free Surface elevation ξ at this place, unit on next time step
N+1
3) with ξ
N+1Substitution formula (6), formula (7) are obtained the flow velocity u of horizontal direction according to the numerical value net flux of each layering
N+1, υ
N+1
4) use the discrete continuity formula (5) of central difference schemes, substitution ξ
N+1, u
N+1, υ
N+1Can obtain ω, obtain vertical velocity ω under the physical coordinates by formula (8) again
N+1
Each subregion is mapped on the computing node on the parallel architecture, and the MPI (Message Passing Interface) of standard is adopted in the communication between node.Adopt and calculate and the overlapping parallel optimization technology of communicating by letter: variable is independently about the calculating in space.At the 1st time step, scanning sequency that there is no harm in the assumed calculation grid is: x → y → z.......For the calculating of a certain direction, can be assumed to the calculating on the x direction.
It calculates to go on foot and can be divided into for 3 steps:
1) calculates internal boundary points on each processor (internal boundary points: refer to be defined in the frontier point of the subregion of each processor t, do not comprise the natural boundary point of finding the solution the zone) about the y direction;
2) data of the internal boundary points on the y direction are carried out the message transmission;
3) calculate interior point (interior point: the non-frontier point that refers to be defined in the subregion on each processor).
Automatically the key step that generates computing grid is as follows:
1) forms the super triangle of universe;
2) divergent boundary inserts frontier point P in order;
3) search comprises the triangle of frontier point P, and this triangle is decomposed into 3 triangles;
4) repeat 2)~3), up to finishing all borders;
5) delete the triangle that all comprise one or more super triangular apex;
6) according to mesh scale control, encrypt the triangulation network, meet the triangular mesh of yardstick up to formation;
7) grid optimization.
Adopt this method at first can realize border self-adaptation (step 2)~3)), can control the triangle yardstick (step 6)) of arbitrfary point then, for generating, the grid of realizing terrain self-adaptive lays a good foundation.
In the above-mentioned steps of the inventive method, step 1 and 2 can effectively will surpass the river information mapping of dimension in mathematical model and computation model, step 3 and 4 can use parallel computation and adaptive mesh carries out data processing fast, obtain meticulous analog simulation result, step 5 is carried out the analysis of gained result of calculation, thereby makes the result who obtains have realistic meaning: ultra-dimension fluvial information is calculated in the meaning of calculating fast in meaning on the planning for water resources development and self-adaptive parallel.
In large hydraulic engineering calculates and plans, owing to not only need the analog simulation river shape of one dimension two dimension, the basin, the water yield and channel net etc., also need three-dimensional analog simulation river, river course, especially more need the data by river history, water quality data etc. carry out the prediction in river and monitoring etc., this is in planning for water resources development and river discharge allocation process, and the dimension of information increases can better support decision-making and planning for water resources development.But dimension increase the increase that can bring calculated amount, especially under the situation of wide basin, so the inventive method adopts the self-adaptive parallel Calculation Method to calculate, can obtain the result in real time fast and effectively, this research for real world applications and digital basin is very significant.
The inventive method dimensional information is abundant, and processing speed is fast, is suitable for large watershed and handles, and its analog simulation display effect is good, dynamically and can accurately show; Can in real time the large hydraulic engineering scheme be carried out meticulous analog simulation fast after adopting the inventive method, greatly reduce the risk and cost of planning, and intuitively science effectively carry out decision support, make the demonstration of large hydraulic engineering scheme enter convenient and swift, the low-cost low-risk epoch.In the system that the inventive method is supported, it is very efficiently that the simulation of hydraulic engineering is revised, and can be real-time demonstrate therefore and the influence that produces.The inventive method is significant aspect the planning and design of hydraulic engineering, based on the fast processing of three-dimensional, can alleviate engineering staff's design burden, and can allow the engineering design degree of progress speed.As do not adopt under the situation of parallel processing, design a dam, may need 1 year even several years, but adopt the inventive method can foreshorten to some months, and design effect is more accurately careful.
Should be understood that above-mentioned description at specific embodiment is comparatively detailed, can not therefore be interpreted as the restriction to scope of patent protection of the present invention, scope of patent protection of the present invention should be as the criterion with claims.
Claims (2)
1. the method for a ultra-dimension fluvial dynamics self-adapting parallel monitoring, it is used for a concurrent computational system that connects parallel data and model bank, and satellite photo and river hydrology data are obtained in this concurrent computational system communication; Said method comprising the steps of:
A, set up the fundamental equation model of various dimensions, will surpass the dimension data input system, classify according to the difference of data dimension of living in; Wherein, super dimension comprises: geographical space dimension, time dimension and relevant information dimension; Described relevant information dimension comprises: water conservancy information and the society relevant with water conservancy are through information;
B, based on the extracting of satellite photo and river hydrology data, the form of multiple information condition with boundary condition joined in the fundamental equation, set up the non-structured grid river dynamics of super dimension model based on tag type high resolving power numerical algorithm; Wherein, boundary condition is: Free Surface border and bottom boundary should satisfy corresponding kinematic and dynamic conditions, and circle, bank normal direction flow velocity is zero; Then given water level in border or flow velocity are opened in the waters;
The efficient parallel computing method of C, the super dimension fluid division of foundation form are carried out interior calculating of dimension and the calculating between dimension;
D, the zoning is divided into a plurality of subregions, each subregion is mapped on the parallel architecture one and calculates on the node, the message passing interface of standard is adopted in communication between node, adopt in adaptive mesh and calculate and the overlapping parallel optimization technology of communicating by letter, variable is independent about the calculating in space;
Adaptive mesh adopts the insertion generation gradually of super triangle among the described step D, comprises that step is as follows:
D1, the super triangle of formation universe;
D2, divergent boundary insert frontier point in order;
D3, search comprise the triangle of this frontier point, and this triangle is decomposed into 3 triangles; Repeat above-mentioned D2~D3 step, up to finishing all borders;
D4, delete the triangle that all comprise one or more super triangular apex;
D5, according to mesh scale control, encrypt the triangulation network, meet the triangular mesh of yardstick up to formation;
D6, grid optimization;
E, set up the ultra-dimension fluvial dynamics numerical model of vertical sigma coordinate based on non-structured grid finite volume method, model adopts quadrilateral and triangle hybrid grid, and the result who calculates gained is carried out data and Changing Pattern comparative analysis.
2. method according to claim 1 is characterized in that, the parallel computation process of described step C comprises:
C1, calculate the internal boundary points on each processor, promptly be defined in the frontier point of the subregion of each processor, do not comprise the natural boundary point of finding the solution the zone about certain direction;
C2, the data of the internal boundary points on this direction are carried out the message transmission;
C3, calculate in point, promptly be defined in the non-frontier point of the subregion on each processor.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN2007101243161A CN101158985B (en) | 2007-10-31 | 2007-10-31 | Ultra-dimension fluvial dynamics self-adapting parallel monitoring method |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN2007101243161A CN101158985B (en) | 2007-10-31 | 2007-10-31 | Ultra-dimension fluvial dynamics self-adapting parallel monitoring method |
Publications (2)
Publication Number | Publication Date |
---|---|
CN101158985A CN101158985A (en) | 2008-04-09 |
CN101158985B true CN101158985B (en) | 2011-06-29 |
Family
ID=39307087
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN2007101243161A Active CN101158985B (en) | 2007-10-31 | 2007-10-31 | Ultra-dimension fluvial dynamics self-adapting parallel monitoring method |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN101158985B (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107944102A (en) * | 2017-11-13 | 2018-04-20 | 武汉大学 | The grid joining method of basin large scale Complex River |
CN108090164A (en) * | 2017-12-13 | 2018-05-29 | 武汉大学 | A kind of basin large scale calculates the coding method of magnanimity grid |
Families Citing this family (14)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101727512B (en) * | 2008-10-17 | 2012-07-04 | 中国科学院过程工程研究所 | General algorithm based on variation multiscale method parallel calculation system |
CN102608282B (en) * | 2011-01-21 | 2015-03-25 | 环境保护部信息中心 | Water quality information computing device and method |
CN102609603B (en) * | 2011-01-21 | 2014-12-31 | 环境保护部信息中心 | Water quality information calculating device and water quality information calculating method |
CN102708227B (en) * | 2012-04-18 | 2015-03-25 | 国家测绘局卫星测绘应用中心 | SPH (smoothed particle hydrodynamics) algorithm-based simulation method and simulation system of process of breaking dam by flood |
CN104200045B (en) * | 2014-09-17 | 2016-01-13 | 武汉大学 | The parallel calculating method of a kind of basin large scale water system sediments formula hydrodynamic model |
CN104318035B (en) * | 2014-11-07 | 2017-05-10 | 中铁第四勘察设计院集团有限公司 | General-to-part type triangular network multi-threading parallel generation method for massive terrain big data cloud |
CN107656468B (en) * | 2017-08-31 | 2020-05-19 | 深圳市盛路物联通讯技术有限公司 | River border line monitoring method and server based on Internet of things |
CN107577894B (en) * | 2017-09-20 | 2020-12-29 | 华中科技大学 | Real-time binary encryption-decryption method for quadrilateral unit |
CN107871041B (en) * | 2017-11-06 | 2019-07-09 | 武汉大学 | The grid processing method of basin complicated landform |
CN109460869B (en) * | 2018-11-06 | 2021-03-12 | 北京英视睿达科技有限公司 | Water environment early warning method and device |
CN110135067B (en) * | 2019-05-16 | 2023-06-16 | 杭州电子科技大学 | Helicopter flow field overlapping mixed grid parallel method under double time step method |
CN110929443B (en) * | 2019-12-02 | 2021-11-30 | 中国水利水电科学研究院 | Two-dimensional flood simulation method based on high-precision terrain generalization |
CN117034662B (en) * | 2023-10-09 | 2023-12-15 | 湖北工业大学 | Space-time conflict quantitative calculation method for arch dam bin surface construction machinery based on system simulation |
CN117787662B (en) * | 2024-02-23 | 2024-05-28 | 中国人民解放军海军工程大学 | Space demand balance partitioning method, electronic equipment and storage medium |
-
2007
- 2007-10-31 CN CN2007101243161A patent/CN101158985B/en active Active
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107944102A (en) * | 2017-11-13 | 2018-04-20 | 武汉大学 | The grid joining method of basin large scale Complex River |
CN107944102B (en) * | 2017-11-13 | 2019-07-09 | 武汉大学 | The grid joining method of basin large scale Complex River |
CN108090164A (en) * | 2017-12-13 | 2018-05-29 | 武汉大学 | A kind of basin large scale calculates the coding method of magnanimity grid |
CN108090164B (en) * | 2017-12-13 | 2019-08-20 | 武汉大学 | A kind of basin large scale calculates the coding method of magnanimity grid |
Also Published As
Publication number | Publication date |
---|---|
CN101158985A (en) | 2008-04-09 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN101158985B (en) | Ultra-dimension fluvial dynamics self-adapting parallel monitoring method | |
Jasiewicz et al. | A new GRASS GIS toolkit for Hortonian analysis of drainage networks | |
Mandli et al. | Adaptive mesh refinement for storm surge | |
Tejedor et al. | Delta channel networks: 2. Metrics of topologic and dynamic complexity for delta comparison, physical inference, and vulnerability assessment | |
CN107180450A (en) | A kind of algorithm of the river valley transverse shape based on DEM | |
Wang et al. | Review on algorithms of dealing with depressions in grid DEM | |
CN102915227A (en) | Parallel method for large-area drainage basin extraction | |
CN113570275A (en) | Water resource real-time monitoring system based on BIM and digital elevation model | |
CN114648617A (en) | Water system extraction method based on digital elevation model DEM | |
CN114925624B (en) | Natural river three-dimensional water flow numerical simulation method | |
Haag et al. | Development of a data model to facilitate rapid watershed delineation | |
Brown et al. | Height and facet extraction from LiDAR point cloud for automatic creation of 3D building models | |
CN116882741A (en) | Method for dynamically and quantitatively evaluating super-standard flood disasters | |
Wang et al. | On the development and verification of a parametric parallel unstructured-grid finite-volume wind wave model for coupling with ocean circulation models | |
Ke et al. | Theory for the curvature dependence of delta front progradation | |
Sun et al. | A simplification method for grid-based DEM using topological hierarchies | |
CN106504325B (en) | A kind of DEM feature point extraction parallel methods based on CUDA | |
Thakur et al. | Exploring CCHE2D and its sediment modelling capabilities | |
CN115758917A (en) | IWIND-LR-based water body algae removal engineering benefit simulation method and device | |
Guo et al. | Research on adaptive tide numerical simulation based on steering dynamic monitoring | |
Li et al. | Application of three-dimensional GIS to water resources | |
Lowe et al. | 1D and 2D Flow Routing on a Terrain | |
Lai | Research and development of Poyang Lake hydrodynamic modeling system based on MapWinGIS | |
Yuan et al. | Geo-Spatial Knowledge and Intelligence: 4th International Conference on Geo-Informatics in Resource Management and Sustainable Ecosystem, GRMSE 2016, Hong Kong, China, November 18-20, 2016, Revised Selected Papers, Part II | |
Roberts et al. | High resolution tsunami inundation simulations |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C06 | Publication | ||
PB01 | Publication | ||
C10 | Entry into substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
C14 | Grant of patent or utility model | ||
GR01 | Patent grant |